Enamines heterocyclic, addition

Two synthetic bridged nitrogen heterocycles are also prepared on a commercial scale. The pentazocine synthesis consists of a reductive alkylation of a pyridinium ring, a remarkable and puzzling addition to the most hindered position, hydrogenation of an enamine, and acid-catalyzed substitution of a phenol derivative. The synthesis is an application of the reactivity rules discussed in the alkaloid section. The same applies for clidinium bromide. 

The synthetic application of reactions based upon the intramolecular addition of a carbanion or its enamine equivalent to a carbonyl or nitrile group has been explored extensively. One class of such reactions, namely the Dieckman, has already been discussed in Section 3.03.2.2, since ring closure can often occur so as to form either the C(2)—C(3) or C(3)—C(4) bond of the heterocyclic ring. Some illustrative examples of the application of this type of ring closure are presented in Scheme 46. 

Read ions of Heterocyclic Enamines with a,p-Unsaturated Compounds Enamines react readily with compounds containing a double bone activated by electronegative groups. Addition of acrolein to 1-methyl-2 ethylidenepyrrolidine, followed by dehydrogenation, leads to 1,7-dimethyl indole (133) (Scheme 9) (215). 

From the addition reaetions of acrolein- to aldehyde-derived enamines, aminotetrahydropyrans have been obtained. On heating, these products rearranged to enaminoaldehydes in examples where the initial enamine was disubstituted (320,321). The addition of acrolein to ketone derived enamines has been applied to syntheses of heterocyclic and bridged bieyclic compounds (301,321-323). 

The reactions of enamines as 1,3-dipolarophiles provide the most extensive examples of applications to heterocyclic syntheses. Thus the addition of aryl azides to a large number of cyclic (596-598) and acyclic (599-602) enamines has led to aminotriazolines which could be converted to triazoles with acid. Particular attention has been given to the direction of azide addition (601,603). While the observed products suggest a transition state in which the development of charges gives greater directional control than steric factors, kinetic data and solvent effects (604-606) speak against zwitterionic intermediates and support the usual 1,3-dipolar addition mechanism. 

Fewer procedures have been explored recently for the synthesis of simple six-membered heterocycles by microwave-assisted MCRs. Libraries of 3,5,6-trisubstituted 2-pyridones have been prepared by the rapid solution phase three-component condensation of CH-acidic carbonyl compounds 44, NJ -dimethylformamide dimethyl acetal 45 and methylene active nitriles 47 imder microwave irradiation [77]. In this one-pot, two-step process for the synthesis of simple pyridones, initial condensation between 44 and 45 under solvent-free conditions was facilitated in 5 -10 min at either ambient temperature or 100 ° C by microwave irradiation, depending upon the CH-acidic carbonyl compound 44 used, to give enamine intermediate 46 (Scheme 19). Addition of the nitrile 47 and catalytic piperidine, and irradiation at 100 °C for 5 min, gave a library of 2-pyridones 48 in reasonable overall yield and high individual purities. 

The reaction of 2-polyfluoroalkylchromones (e.g., 323) with l,3,3-dimethyl-3,4-dihydroisoquinolines (e.g., 324) gave zwitterionic 6,7-dihydrobenzo[ ]quinolizinium compounds such as 326 (Scheme 70). The mechanism proposed for this transformation involves an addition-elimination displacement of the chromane heterocyclic oxygen by the enamine tautomer of the dihydroisoquinoline, followed by intramolecular cyclization of the intermediate 325 <20030L3123>. 

Imines and enamines under hydroformylation conditions can also be reduced to give saturated amines. With or without additional reduction, these conversions can be used in synthesis of various types of heterocycles. 

Domino processes can also be performed on open-chain compounds. MacMillan and co-workers demonstrated this with their own imidazolidinone catalysts. Conjugate addition of a nucleophilic heterocycle 231 to the a,(i-unsaturated enal 230 followed by a-chlorination of the resulting enamine led to the syn products 234 in very high enantioselectivities and good sytv.anti diastereoselectivities (Scheme 38) [347]. Similar domino sequences, but with different nucleophile-electrophile partners, were also reported independently by Jprgensen [348]. 

Reduction of quinolines in acid solution at a lead cathode or by dissolving zinc leads to attack on the heterocyclic ring with the formation of 4,4-coupled products, together with the tetrahydroquinoline [82,83]. In the case of 2- and 4-methyl substituted quinolines, dimeric products are obtained in 10 90 % yields. In these processes, dimerization of the one-electron addition product is in competition with further reduction to give the 1,4-dihydroquinoline, The latter is an enamine and it... 

Hydroamination of Alkynes The discovery of palladium-catalyzed intramolecular addition of amines to acetylene coupled with the spectacular contribution of Hutchings opened the door for the synthesis of several nitrogen heterocycles. The first study in this field was performed by Utimoto et al., who researched gold catalyzed intramolecular 6-exo-dig hydroamination. Tautomerization of the initial enamines allowed them to obtain imines, which were thermodynamically more stable [111] (Scheme 8.20). 

High temperature, pressure, and catalyst are required to achieve addition of ammonia to alkynes. Acetylene and ammonia yield a complex mixture of heterocyclic nitrogen bases.311,312 Ethylideneimines, thought to form through the intermediate enamines, are the products of the reaction of acetylene with primary alkylamines in the presence of catalysts.313... 

There is a rich synthetic potential for enamines in heterocyclic synthesis. Enamines can react as electrophiles or nucleophiles and as new partners in cycloaddition reactions. Various derivatives of nitrogen-, oxygen-, and sulfur-containing heterocycles have been prepared, and these, in turn, are of interest as starting materials for additional syntheses. They represent potential synthons for the development of various new directions in organic chemistry. 

Bicyclic keto esters can easily be prepared by a process called a,a -annulation.29 Thus, treatment of the enamine of cyclopentanone (64) with ethyl a-(bromomethyl)acrylate (98) affords, after work-up, the bicyclic keto ester (99) in 80% yield (equation IS).2911 The mechanism probably involves an initial Michael addition and elimination (or a simple Sn2 or Sn2 alkylation) followed by an intramolecular Michael addition of the less-substituted enamine on the acrylate unit. The use of the enamine of 4,4-bis(ethoxycarbonyl)cyclohexanone (100 equation 26) with (98) gives a 45% yield of the adaman-tanedione diester (101) (yield based on 100 70% when based on 98) via a,a -annulation followed by Dieckmann condensation.29 Enamines of heterocyclic ketones can also serve as the initial nucleophiles, e.g. (102) and (103) give (105) via (104), formed in situ, in 70% yield (Scheme 11 ).29>... 

A pyrrolidine-thiourea organocatalyst (69) facilitates Michael addition of cyclohexanone to both aryl and alkyl nitroalkenes with up to 98% de and ee 202 The bifunctional catalyst (69) can doubly hydrogen bond to the nitro group, leaving the chiral heterocycles positioned for cyclohexyl enamine formation over one face of the alkene. 

Selective and efficient Michael additions of heterocyclic enamines (e.g. indoles, pyrroles, and pyrazoles) to enones can be catalysed by ZrCU (2 mol%).150 Michael addition of a - cy an o k e t e n e -. V,. S - ac et al s (RS)2C=CHCN to enones R CH=CHCOR2 can be promoted by TiCl4.151 Addition of the lithium enolate, generated from (2S,5S)- (g) c -l,3-dioxolan-4-one, which in turn was prepared from (S)-mandelic acid and pival-aldehyde, to several 2-arylidene-1,3-diketones, gives the Michael adducts in good yields and diastereoselectivities.152... 

Aminoquinolines 62 have been prepared in a two-step, one-pot, three-component reaction of 2-azidobenzophenones, secondary amines and arylac-etaldehydes [110]. The microwave-assisted reaction proceeded via the initial formation of enamines 59. Subsequent addition of 2-azidobenzophenones 60 afforded the triazoline intermediates 61, which underwent thermal rearrangement and cyclocondensation to furnish 2-aminoquinolines 62 (Scheme 41). Direct comparison with conventional thermal conditions demonstrated the superiority of microwave dielectric heating in terms of yields (73% vs. 31% of heterocycle 63 after 10 min at 180 °C). Furthermore, the formation of by-products due to decomposition of azide 60 was diminished in the microwave-assisted synthesis. Purification of the products was achieved using solid-phase extraction techniques. 

The use of palladium-based chemistry continues to generate methods for heterocyclic synthesis. In a four-component reaction, ring-fused pyridines can be synthesized in one pot, referred to as a coupling-isomerization-enamine addition-cyclocondensation sequence (Scheme 106) <2005EJ01834>. 

Many common reactions of aliphatic amines, ethers, and sulfides 1 involve initial addition of an electrophilic reagent utilizing the lone pair of electrons on the heteroatom salts, quaternary salts, coordination compounds, amine oxides, sulfoxides, and sulfones are formed in this way. Corresponding reactions are very rare (cf. Section 3.3.1.3) with pyrroles, furans, and thiophenes. These heterocycles react with electrophilic reagents at the carbon atoms 2, 3 rather than at the heteroatom. Vinyl ethers and enamines 4 show intermediate behavior, reacting frequently at the -carbon but sometimes at the heteroatom. 

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